JPH10104070A - Frequency standard and method for forming selected standard frequency - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the frequency standard of a simple constitution, which can obtain a plurality of standard frequencies at an equal frequency interval and can readily select the light of any frequency among a plurality of the standard frequencies without degrading accuracy. SOLUTION: This frequency standard 10 has an etalon 12, which determines a plurality of standard frequencies comprising transmittable frequencies by transmitting only the lights of a plurality of the frequencies at the equal frequency interval of 100GHz, and a frequency selecting filter 14, which selects any frequency among the standard frequencies as the selected standard frequency, on an optical path 16 in the mutually series pattern.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to a wavelength standard device and a standard wavelength generation method suitable for use in optical communication, optical measurement, and optical device manufacturing, and particularly wavelength multiplexing communication.

[0002]

2. Description of the Related Art In optical wavelength multiplex communication, signals of a plurality of channels are transmitted using a common optical fiber. Each of these channels is assigned a plurality of frequencies at a fixed frequency interval. In optical wavelength multiplex communication, it is necessary to prevent signals of different channels from interfering with each other. To do so, the transmission system,
In the entire communication system including the reception system and the propagation system between the transmission system and the reception system, the frequency of each channel needs to be the same.

[0003] In August 1996, ITU-T (International Telecommunication Union Telecommunications Research Committee), which is an international organization, designated "Nom" as the frequency of light used for optical wavelength division multiplexing communication.
An international standard has been determined, referred to as "inal Central Frequencies". Hereinafter, for convenience, a plurality of frequencies determined by the international standard will be referred to as “standard frequencies”.

[0004] As a result of the determination of the standard frequency, when manufacturing and maintaining equipment used for optical wavelength division multiplexing communication, and constructing and maintaining a communication system for optical wavelength division multiplexing communication, which of these multiple standard frequencies is used. It is considered that a frequency standard that can be obtained as needed even with light of a frequency is required.

Conventionally, there is no known dedicated device for such a frequency standard. Therefore, it is conceivable to construct such a frequency standard using, for example, a spectrum analyzer or a fiber grating.

[0006]

However, when a spectrum analyzer is used as a frequency standard, the wavelength of the measurement light can be measured by the spectrum analyzer, but the light source must be prepared separately from the spectrum analyzer. No.

When a fiber grating is used as a frequency standard, a light source and a fiber grating must be prepared for each standard frequency. As a result, since the structure of the device becomes complicated, the yield of the device may be degraded and the cost of the device may be increased.

Therefore, a plurality of standard frequencies at equal frequency intervals can be obtained with high accuracy, and light of any one of the plurality of standard frequencies can be easily selected without lowering the accuracy. It has been desired to realize a frequency standard device having a configuration and a method of generating a selected standard frequency.

[0009]

According to the frequency standard of the first invention of the present application, by transmitting only light of a plurality of frequencies at equal frequency intervals, a plurality of standard frequencies consisting of frequencies that can be transmitted are transmitted. , And a frequency selection filter for selecting any one of the standard frequencies as the selected standard frequency are provided in series on the optical path of the laser light.

[0010] According to the method for generating a selected standard wavelength of the second invention according to this application, an etalon and a frequency selection filter are provided in series on the optical path of laser light, and the etalon can be transmitted by the etalon. A plurality of standard frequencies at equal frequency intervals are determined, and one of the standard wavelengths is selected as a selected standard frequency by a frequency selection filter.

As described above, according to the frequency standard device of the first invention and the selected standard frequency generation method of the second invention, the etalon is used to determine a plurality of standard frequencies at equal frequency intervals. The etalon has a property of transmitting only light having a frequency of discrete values at equal frequency intervals. The frequency of the light that can pass through the etalon is physically determined by the thickness of the etalon if the incident angle of the light to the etalon and the temperature conditions are constant. The accuracy of the standard frequency determined by the etalon is determined by the parallelism, the surface accuracy, and the reflectance of both sides of the etalon.

According to these inventions, light of a desired frequency is selected from the standard frequencies determined by the etalon by the frequency selection filter. That is, even if the frequency selected by the frequency selection filter changes continuously, the frequency that can be extracted is limited to the standard frequency of discrete values determined by the etalon. Therefore, even if the frequency accuracy selected by the frequency selection filter is low, a desired frequency (selected standard frequency) can be easily selected from the standard frequencies without lowering the accuracy.

As a result, according to these inventions, a highly accurate selected standard frequency can be easily obtained so as to switch channels.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, with reference to the drawings, embodiments of a frequency standard according to the first invention and a method for generating a selected standard frequency according to a second invention will be described together. The drawings referred to merely schematically show the sizes, shapes, and arrangements of the components so that these inventions can be understood. Therefore, these inventions are not limited to the illustrated examples.

FIG. 1 shows the configuration of a frequency standard according to this embodiment. The frequency standard device 10 transmits only light of a plurality of frequencies at equal frequency intervals, thereby determining an etalon 12 for determining a plurality of standard frequencies including the frequencies that can be transmitted, and any one of these standard frequencies. A frequency selection filter 14 for selecting such a frequency as a selection standard frequency is provided on the optical path 16 in series with each other.

Light is incident on the frequency standard device 10 from an incident side optical fiber 18. The incident light need not be limited to laser light, but here, a wavelength of 150 is used.
A laser beam of about 0 nm is incident.

Light incident from the incident side optical fiber 18 is incident on the incident side collimator 20 and the incident side isolator 2.
2 sequentially pass through and enter the etalon 12.

The etalon 12 is composed of the etalon 1
2, only light of a plurality of standard frequencies at equal frequency intervals is transmitted. The standard frequency is determined by the temperature and thickness of the etalon 12. The temperature of the etalon 12 is controlled by a Peltier device 24 provided in contact with the etalon 12. Here, an etalon having a thickness of about 2 mm and a reflectivity of 95% is used.

The frequency interval Δν of the standard frequency transmitted through the etalon 12 is given by the following equation (1).

Δν = c / 2ln (1) where c is the speed of light, l is the thickness of the etalon, and n is the refractive index of the etalon.

Incidentally, the standard frequency transmitted through the etalon 12 can also be controlled by the incident angle of light to the etalon 12. However, it is desirable to make the light substantially perpendicular to the incident surface of the etalon 12. This is because the smaller the angle of incidence of the etalon 12 with respect to the normal of the plane of incidence,
This is because light loss is reduced.

The light of the standard frequency transmitted through the etalon 12 enters the frequency selection filter 14. In this embodiment, a transmission type filter 14 is used. This filter is
It is composed of a dielectric multilayer film. The transmission frequency of the filter 14 changes depending on the incident angle of light on the filter. Therefore, this filter 14
Selects one of a plurality of standard frequencies as a selected standard frequency by changing an incident angle. In FIG. 1, the illustration of the rotation mechanism of the filter 14 is omitted.

The light of the selected standard frequency transmitted through the filter 14 is transmitted through the output side isolator 26 and the output side collimator 28 sequentially, and is output from the output side optical fiber 30. In this way, a selected standard frequency can be generated.

Next, the selection of the frequency by the etalon 12 and the filter 14 will be described with reference to FIG.
2A to 2C show transmission frequency characteristics, and FIG.
The horizontal axis of (A) to (C) represents frequency (arbitrary unit),
The vertical axis represents light transmission intensity (arbitrary unit).

FIG. 2A is a schematic diagram showing transmission frequency characteristics of the etalon. A plurality of standard frequencies at equal frequency intervals can be obtained. Further, a frequency interval Δf of the transmission peak I of each standard frequency is, for example, about 100 GHz, and a finesse of about 10 to 20 can be easily obtained.

FIG. 2B is a schematic diagram showing the transmission frequency characteristics of the filter. The half width of the transmission peak II is wider than the half width of each transmission peak I of the etalon. The half-width of the transmission peak II is
Those having a thickness of about 0.5 nm can be easily obtained.

FIG. 2C is a schematic diagram in which the transmission frequency characteristic of the etalon and the transmission frequency characteristic of the filter are superimposed. Multiple transmission peaks I of etalon
Of these, only the transmission peak P included in the transmission peak II of the filter is selected as light of the selected standard frequency. The precision of the selected standard frequency is determined by the etalon. This is because the half width of the transmission peak I of the etalon is narrower than the half width of the transmission peak II of the filter, and the etalon cuts off light having a frequency between the transmission peaks I, and the transmission peak I is determined. It is because. Therefore, even if the transmission frequency of the filter continuously changes, the selected standard frequency that can be extracted is limited to the standard frequency of discrete values determined by the etalon. Therefore, even if the frequency accuracy selected by the frequency selection filter is lower than the accuracy of the standard frequency transmitting the etalon, a desired frequency (selected standard frequency) can be easily selected from the standard frequencies without lowering the accuracy. be able to.

[0028]

Next, with reference to FIG. 3, it will be described that the accuracy of the selected standard frequency is determined not by the filter but by the etalon. FIG. 3 is a graph showing a measurement result of a relationship between a scale value of a micrometer for adjusting an incident angle with respect to a filter and a selected standard frequency of light output from a frequency standard device. The horizontal axis in FIG. 3 represents the value of the micrometer scale, and the vertical axis represents the frequency (THz). The value of the micrometer scale corresponds to the angle of incidence of light on the filter, and the angle of incidence corresponds to the transmission frequency of the filter. Therefore, the horizontal axis of the graph in FIG. 3 corresponds to the transmission frequency of the filter.

As shown in the graph of FIG. 3, even if the transmission frequency of the filter is changed by turning the scale of the micrometer, if the transmission frequency of the filter is within a certain range, the value of the selected standard frequency is constant. . When the transmission frequency of the filter is changed by a certain value or more, the selected standard frequency becomes 5
Move to a value separated by 0 GHz. In this way, the selected standard frequency changes stepwise.

Accordingly, from the graph of FIG. 3, even if the transmission frequency of the filter does not exactly match the desired selected standard frequency, in other words, even if the transmission frequency of the filter slightly deviates from the desired selected standard frequency, the deviation of the filter can be obtained. It can be seen that if the size is within a certain range, a desired selected standard frequency can be easily obtained without lowering the accuracy. Therefore, according to the present invention, an accurate selected standard frequency can be easily obtained so as to switch channels.

Next, the graph of FIG. 4 shows the measurement results of the transmission wavelength characteristics of the etalon. The horizontal axis of the graph in FIG. 4 represents the wavelength (nm), and the vertical axis represents the light transmission intensity (dBm).
As shown by a curve III in the graph of FIG. 4, peaks appear at wavelengths at substantially equal intervals. However, since the frequency intervals are equal, the wavelength intervals are not exactly equal. FIG.
Although the frequency corresponding to the transmission wavelength of the peak shown in the graph is not the value of the standard frequency described above, there is no problem in matching this with the value of the standard frequency by changing the thickness of the etalon and the temperature conditions.

Next, the graph of FIG. 5 shows the measurement results of the output of the frequency standard. The horizontal axis of the graph of FIG.
m), and the vertical axis represents light intensity (dBm). The output shown in the graph of FIG. 5 is the peak of the transmission wavelength shown in the graph of FIG.
The wavelength of the peak P ₃ in the vicinity of 3.7 nm, is obtained by selection by the filter. Also, the peak on both sides peak P ₃ that is selected, there is sufficient difference in light intensity of a few dBm.

In the embodiments and examples described above, only examples in which these inventions are configured under specific conditions have been described. However, these inventions can be subjected to many changes and modifications. For example, in the above-described embodiment,
Although the light that has passed through the etalon first enters the frequency selection filter, in these inventions, the light that has passed through the frequency selection filter first may enter the etalon. That is, the order of incidence of light on the etalon and the frequency selection filter is not limited.

For example, in the above-described embodiment,
As the frequency selection filter, a transmission type filter whose transmission frequency changes according to the incident angle of light is used. In these inventions, various types of filters can be used. For example, a so-called “non-polarization type wavelength tunable filter” whose transmission frequency changes depending on the light transmission position can be used as the frequency selection filter.

In these inventions, the frequency selection filter does not need to be limited to a transmission type filter. For example, a grating can be used as the frequency selection filter. Note that the use of a grating as a frequency selection filter is different from the case where the wavelength is selected only by the grating described in the section of the related art. That is, in the present invention, since a plurality of standard frequencies are determined by the etalon, even if the setting of the grating as the frequency selection filter is slightly shifted,
If the magnitude of the deviation is within a certain range, a desired selected standard frequency can be selected from the standard frequencies without lowering the accuracy.

[0036]

According to the frequency standard device of the first invention and the selected standard frequency generation method of the second invention, an etalon is used to determine a plurality of standard frequencies at equal frequency intervals. Then, light of a desired frequency is selected from the standard frequencies by a frequency selection filter. As a result, even if the frequency selected by the frequency selection filter changes continuously, the frequency that can be extracted is limited to the standard frequency of discrete values determined by the etalon. Therefore, even if the frequency accuracy selected by the frequency selection filter is lower than the accuracy of the standard frequency transmitting the etalon, a desired selected standard frequency can be easily selected from the standard frequencies without lowering the accuracy. . Therefore, with a simple configuration, it is possible to accurately obtain a plurality of standard frequencies at equal frequency intervals, and to easily select light of any one of the plurality of standard frequencies without lowering the accuracy. it can.

[Brief description of the drawings]

FIG. 1 is a configuration diagram for explaining a frequency standard according to an embodiment;

FIG. 2A is a schematic diagram illustrating transmission frequency characteristics of an etalon, FIG. 2B is a schematic diagram illustrating transmission frequency characteristics of a filter, and FIG. 2C is a schematic diagram illustrating transmission frequency characteristics of an etalon and a filter. FIG.

FIG. 3 is a graph showing a measurement result of a relationship between a scale value of a micrometer and a selected standard frequency.

FIG. 4 is a graph showing measurement results of transmission wavelength characteristics of an etalon.

FIG. 5 is a graph showing a measurement result of an output of the frequency standard device.

[Explanation of symbols]

 10: Frequency standard 12: Etalon 14: Frequency selection filter, filter 16: Optical path 18: Incident side optical fiber 20: Incident side collimator 22: Incident side isolator 24: Peltier element 26: Exit side isolator 28: Exit side collimator 30: Exit optical fiber

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Yoshitaka Nawahira 2-3-2 Nishi-Shinjuku, Shinjuku-ku, Tokyo International Telegraph and Telephone Corporation

Claims (2)

[Claims] An etalon for determining a plurality of standard frequencies composed of the frequencies that can be transmitted by transmitting only light of a plurality of frequencies at equal frequency intervals, and any one of the standard frequencies. A frequency standard device comprising a frequency selection filter for selecting a selected standard frequency in series on an optical path. 2. An etalon and a frequency selection filter are provided in series on an optical path, and a plurality of standard frequencies at equal frequency intervals through which the etalon can be transmitted are determined by the etalon. A method for generating a selected standard frequency, wherein any one of the wavelengths is selected as a selected standard frequency.